TY - GEN
T1 - A novel cross-scale nanopositioning stage based on dual piezoelectric stick-slip actuation with a shared flexible hinge
AU - Meng, Siyuan
AU - Zhu, Junhui
AU - Wang, Yong
AU - Shi, Luoning
AU - Yu, Jia
AU - Wu, Dongmei
AU - Dong, Wei
AU - Ru, Changhai
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - This paper presents a novel cross-scale nanopositioning stage that integrates the advantages of piezoelectric stick-slip positioners and piezoelectric scanners, utilizing the concept of macro-micro positioning.Initially, a unique structural design featuring a single flexible hinge shared by a small and a large PZT is proposed to reduce the stage's size effectively, enabling millimeter-scale strokes with nanometer-scale positioning accuracy.Subsequently, the cross-scale motion generation mechanism of the dual piezoelectric stick-slip drive is investigated, leading to the development of a system-level dynamics model for the proposed positioning stages.The mechanism design is further optimized to enhance performance.A prototype is manufactured, and a series of experiments are conducted to evaluate the stage's performance.Results indicate that the proposed positioning stage achieves a maximum motion range of 20 mm and a minimum step length of 70 nm in small piezoceramic macro-motion stepping mode, along with a maximum scanning range of 4.9 μm and a motion resolution of 16 nm in large piezoceramic micro-motion scanning mode.Moreover, the compact structure of the stage (30×17×8 mm3) supports a maximum motion speed of 10 mm/s and a maximum load of 2 kg.Experimental validation confirms the feasibility of the proposed stage, demonstrating nanometer positioning resolution, high accuracy, high speed, and large travel range.These attributes highlight the significant potential of the proposed stage in various in-situ SEM nanorobotic instrument systems.
AB - This paper presents a novel cross-scale nanopositioning stage that integrates the advantages of piezoelectric stick-slip positioners and piezoelectric scanners, utilizing the concept of macro-micro positioning.Initially, a unique structural design featuring a single flexible hinge shared by a small and a large PZT is proposed to reduce the stage's size effectively, enabling millimeter-scale strokes with nanometer-scale positioning accuracy.Subsequently, the cross-scale motion generation mechanism of the dual piezoelectric stick-slip drive is investigated, leading to the development of a system-level dynamics model for the proposed positioning stages.The mechanism design is further optimized to enhance performance.A prototype is manufactured, and a series of experiments are conducted to evaluate the stage's performance.Results indicate that the proposed positioning stage achieves a maximum motion range of 20 mm and a minimum step length of 70 nm in small piezoceramic macro-motion stepping mode, along with a maximum scanning range of 4.9 μm and a motion resolution of 16 nm in large piezoceramic micro-motion scanning mode.Moreover, the compact structure of the stage (30×17×8 mm3) supports a maximum motion speed of 10 mm/s and a maximum load of 2 kg.Experimental validation confirms the feasibility of the proposed stage, demonstrating nanometer positioning resolution, high accuracy, high speed, and large travel range.These attributes highlight the significant potential of the proposed stage in various in-situ SEM nanorobotic instrument systems.
UR - https://www.scopus.com/pages/publications/85202354709
U2 - 10.1109/MARSS61851.2024.10612733
DO - 10.1109/MARSS61851.2024.10612733
M3 - 会议稿件
AN - SCOPUS:85202354709
T3 - Proceedings of MARSS 2024 - 7th International Conference on Manipulation, Automation, and Robotics at Small Scales
BT - Proceedings of MARSS 2024 - 7th International Conference on Manipulation, Automation, and Robotics at Small Scales
A2 - Haliyo, Sinan
A2 - Boudaoud, Mokrane
A2 - Mastrangeli, Massimo
A2 - Lambert, Pierre
A2 - Fatikow, Sergej
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 7th International Conference on Manipulation, Automation, and Robotics at Small Scales, MARSS 2024
Y2 - 1 July 2024 through 5 July 2024
ER -